/** * @file kernel/vfs/pipe.c * @brief Legacy buffered pipe, used for char devices. * * This is the legacy pipe implementation. If you are looking for * the userspace pipes, @ref read_unixpipe. * * This implements a simple one-direction buffer suitable for use * by, eg., device drivers that want to offer a character-driven * interface to userspace without having to worry too much about * timing or getting blocked. * * @copyright * This file is part of ToaruOS and is released under the terms * of the NCSA / University of Illinois License - see LICENSE.md * Copyright (C) 2012-2021 K. Lange */ #include #include #include #include #include #include #include #include #include #include #include #include #define DEBUG_PIPES 0 static inline size_t pipe_unread(pipe_device_t * pipe) { if (pipe->read_ptr == pipe->write_ptr) { return 0; } if (pipe->read_ptr > pipe->write_ptr) { return (pipe->size - pipe->read_ptr) + pipe->write_ptr; } else { return (pipe->write_ptr - pipe->read_ptr); } } int pipe_size(fs_node_t * node) { pipe_device_t * pipe = (pipe_device_t *)node->device; spin_lock(pipe->ptr_lock); int out = pipe_unread(pipe); spin_unlock(pipe->ptr_lock); return out; } static inline size_t pipe_available(pipe_device_t * pipe) { if (pipe->read_ptr == pipe->write_ptr) { return pipe->size - 1; } if (pipe->read_ptr > pipe->write_ptr) { return pipe->read_ptr - pipe->write_ptr - 1; } else { return (pipe->size - pipe->write_ptr) + pipe->read_ptr - 1; } } int pipe_unsize(fs_node_t * node) { pipe_device_t * pipe = (pipe_device_t *)node->device; spin_lock(pipe->ptr_lock); int out = pipe_available(pipe); spin_unlock(pipe->ptr_lock); return out; } static inline void pipe_increment_read(pipe_device_t * pipe) { spin_lock(pipe->ptr_lock); pipe->read_ptr++; if (pipe->read_ptr == pipe->size) { pipe->read_ptr = 0; } spin_unlock(pipe->ptr_lock); } static inline void pipe_increment_write(pipe_device_t * pipe) { spin_lock(pipe->ptr_lock); pipe->write_ptr++; if (pipe->write_ptr == pipe->size) { pipe->write_ptr = 0; } spin_unlock(pipe->ptr_lock); } static inline void pipe_increment_write_by(pipe_device_t * pipe, size_t amount) { pipe->write_ptr = (pipe->write_ptr + amount) % pipe->size; } static void pipe_alert_waiters(pipe_device_t * pipe) { spin_lock(pipe->alert_lock); while (pipe->alert_waiters->head) { node_t * node = list_dequeue(pipe->alert_waiters); process_t * p = node->value; free(node); spin_unlock(pipe->alert_lock); process_alert_node(p, pipe); spin_lock(pipe->alert_lock); } spin_unlock(pipe->alert_lock); } uint64_t read_pipe(fs_node_t *node, uint64_t offset, uint64_t size, uint8_t *buffer) { /* Retreive the pipe object associated with this file node */ pipe_device_t * pipe = (pipe_device_t *)node->device; if (pipe->dead) { send_signal(this_core->current_process->id, SIGPIPE, 1); return 0; } size_t collected = 0; while (collected == 0) { spin_lock(pipe->lock_read); while (pipe_unread(pipe) > 0 && collected < size) { buffer[collected] = pipe->buffer[pipe->read_ptr]; pipe_increment_read(pipe); collected++; } spin_unlock(pipe->lock_read); wakeup_queue(pipe->wait_queue_writers); /* Deschedule and switch */ if (collected == 0) { sleep_on(pipe->wait_queue_readers); } } return collected; } uint64_t write_pipe(fs_node_t *node, uint64_t offset, uint64_t size, uint8_t *buffer) { /* Retreive the pipe object associated with this file node */ pipe_device_t * pipe = (pipe_device_t *)node->device; if (pipe->dead) { send_signal(this_core->current_process->id, SIGPIPE, 1); return 0; } size_t written = 0; while (written < size) { spin_lock(pipe->lock_write); /* These pipes enforce atomic writes, poorly. */ if (pipe_available(pipe) > size) { while (pipe_available(pipe) > 0 && written < size) { pipe->buffer[pipe->write_ptr] = buffer[written]; pipe_increment_write(pipe); written++; } } spin_unlock(pipe->lock_write); wakeup_queue(pipe->wait_queue_readers); pipe_alert_waiters(pipe); if (written < size) { sleep_on(pipe->wait_queue_writers); } } return written; } void open_pipe(fs_node_t * node, unsigned int flags) { /* Retreive the pipe object associated with this file node */ pipe_device_t * pipe = (pipe_device_t *)node->device; /* Add a reference */ pipe->refcount++; return; } void close_pipe(fs_node_t * node) { /* Retreive the pipe object associated with this file node */ pipe_device_t * pipe = (pipe_device_t *)node->device; /* Drop one reference */ pipe->refcount--; /* Check the reference count number */ if (pipe->refcount == 0) { #if 0 /* No other references exist, free the pipe (but not its buffer) */ free(pipe->buffer); list_free(pipe->wait_queue); free(pipe->wait_queue); free(pipe); /* And let the creator know there are no more references */ node->device = 0; #endif } return; } static int pipe_check(fs_node_t * node) { pipe_device_t * pipe = (pipe_device_t *)node->device; if (pipe_unread(pipe) > 0) { return 0; } return 1; } static int pipe_wait(fs_node_t * node, void * process) { pipe_device_t * pipe = (pipe_device_t *)node->device; spin_lock(pipe->alert_lock); if (!list_find(pipe->alert_waiters, process)) { list_insert(pipe->alert_waiters, process); } spin_unlock(pipe->alert_lock); spin_lock(pipe->wait_lock); list_insert(((process_t *)process)->node_waits, pipe); spin_unlock(pipe->wait_lock); return 0; } fs_node_t * make_pipe(size_t size) { fs_node_t * fnode = malloc(sizeof(fs_node_t)); pipe_device_t * pipe = malloc(sizeof(pipe_device_t)); memset(fnode, 0, sizeof(fs_node_t)); memset(pipe, 0, sizeof(pipe_device_t)); fnode->device = 0; fnode->name[0] = '\0'; snprintf(fnode->name, 100, "[pipe]"); fnode->uid = 0; fnode->gid = 0; fnode->mask = 0666; fnode->flags = FS_PIPE; fnode->read = read_pipe; fnode->write = write_pipe; fnode->open = open_pipe; fnode->close = close_pipe; fnode->readdir = NULL; fnode->finddir = NULL; fnode->ioctl = NULL; /* TODO ioctls for pipes? maybe */ fnode->get_size = pipe_size; fnode->selectcheck = pipe_check; fnode->selectwait = pipe_wait; fnode->atime = now(); fnode->mtime = fnode->atime; fnode->ctime = fnode->atime; fnode->device = pipe; pipe->buffer = malloc(size); pipe->write_ptr = 0; pipe->read_ptr = 0; pipe->size = size; pipe->refcount = 0; pipe->dead = 0; spin_init(pipe->lock_read); spin_init(pipe->lock_write); spin_init(pipe->alert_lock); spin_init(pipe->wait_lock); spin_init(pipe->ptr_lock); pipe->wait_queue_writers = list_create("pipe writers",pipe); pipe->wait_queue_readers = list_create("pip readers",pipe); pipe->alert_waiters = list_create("pipe alert waiters",pipe); return fnode; }